ref: e447c9fb929e61a40203b0193ee8d4cab8d72f7e
dir: /DoConfig/fltk/src/ps_image.cxx/
// // "$Id: image.cxx 4324 2005-05-09 21:47:22Z rokan $" // // Postscript image drawing implementation for the Fast Light Tool Kit (FLTK). // // Copyright 1998-2015 by Bill Spitzak and others. // // This library is free software. Distribution and use rights are outlined in // the file "COPYING" which should have been included with this file. If this // file is missing or damaged, see the license at: // // http://www.fltk.org/COPYING.php // // Please report all bugs and problems on the following page: // // http://www.fltk.org/str.php // #ifndef FL_DOXYGEN #include <stdio.h> #include <math.h> #include <string.h> #include <FL/Fl_PostScript.H> #include <FL/Fl.H> #include <FL/Fl_Pixmap.H> #include <FL/Fl_Bitmap.H> // // Implementation of the /ASCII85Encode PostScript filter // as described in "PostScript LANGUAGE REFERENCE third edition" p. 131 // struct struct85 { uchar bytes4[4]; // holds up to 4 input bytes int l4; // # of unencoded input bytes int blocks; // counter to insert newlines after 80 output characters uchar chars5[5]; // holds 5 output characters }; void *Fl_PostScript_Graphics_Driver::prepare85() // prepare to produce ASCII85-encoded output { struct85 *big = new struct85; big->l4 = 0; big->blocks = 0; return big; } // ASCII85-encodes 4 input bytes from bytes4 into chars5 array // returns # of output chars static int convert85(const uchar *bytes4, uchar *chars5) { if (bytes4[0] == 0 && bytes4[1] == 0 && bytes4[2] == 0 && bytes4[3] == 0) { chars5[0] = 'z'; return 1; } unsigned val = bytes4[0]*(256*256*256) + bytes4[1]*(256*256) + bytes4[2]*256 + bytes4[3]; chars5[0] = val / 52200625 + 33; // 52200625 = 85 to the 4th val = val % 52200625; chars5[1] = val / 614125 + 33; // 614125 = 85 cube val = val % 614125; chars5[2] = val / 7225 + 33; // 7225 = 85 squared val = val % 7225; chars5[3] = val / 85 + 33; chars5[4] = val % 85 + 33; return 5; } void Fl_PostScript_Graphics_Driver::write85(void *data, const uchar *p, int len) // sends len input bytes for ASCII85 encoding { struct85 *big = (struct85 *)data; const uchar *last = p + len; while (p < last) { int c = 4 - big->l4; if (last-p < c) c = last-p; memcpy(big->bytes4 + big->l4, p, c); p += c; big->l4 += c; if (big->l4 == 4) { c = convert85(big->bytes4, big->chars5); fwrite(big->chars5, c, 1, output); big->l4 = 0; if (++big->blocks >= 16) { fputc('\n', output); big->blocks = 0; } } } } void Fl_PostScript_Graphics_Driver::close85(void *data) // stops ASCII85-encoding after processing remaining unencoded input bytes, if any { struct85 *big = (struct85 *)data; int l; if (big->l4) { // # of remaining unencoded input bytes l = big->l4; while (l < 4) big->bytes4[l++] = 0; // complete them with 0s l = convert85(big->bytes4, big->chars5); // encode them if (l == 1) memset(big->chars5, '!', 5); fwrite(big->chars5, big->l4 + 1, 1, output); } fputs("~>", output); // write EOD mark delete big; } // // End of implementation of the /ASCII85Encode PostScript filter // // // Implementation of the /RunLengthEncode + /ASCII85Encode PostScript filter // as described in "PostScript LANGUAGE REFERENCE third edition" p. 142 // struct struct_rle85 { struct85 *data85; // aux data for ASCII85 encoding uchar buffer[128]; // holds non-run data int count; // current buffer length int run_length; // current length of run }; void *Fl_PostScript_Graphics_Driver::prepare_rle85() // prepare to produce RLE+ASCII85-encoded output { struct_rle85 *rle = new struct_rle85; rle->count = 0; rle->run_length = 0; rle->data85 = (struct85*)prepare85(); return rle; } void Fl_PostScript_Graphics_Driver::write_rle85(uchar b, void *data) // sends one input byte to RLE+ASCII85 encoding { struct_rle85 *rle = (struct_rle85 *)data; uchar c; if (rle->run_length > 0) { // if within a run if (b == rle->buffer[0] && rle->run_length < 128) { // the run can be extended rle->run_length++; return; } else { // output the run c = (uchar)(257 - rle->run_length); write85(rle->data85, &c, 1); // the run-length info write85(rle->data85, rle->buffer, 1); // the byte of the run rle->run_length = 0; } } if (rle->count >= 2 && b == rle->buffer[rle->count-1] && b == rle->buffer[rle->count-2]) { // about to begin a run if (rle->count > 2) { // there is non-run data before the run in the buffer c = (uchar)(rle->count-2 - 1); write85(rle->data85, &c, 1); // length of non-run data write85(rle->data85, rle->buffer, rle->count-2); // non-run data } rle->run_length = 3; rle->buffer[0] = b; rle->count = 0; return; } if (rle->count >= 128) { // the non-run buffer is full, output it c = (uchar)(rle->count - 1); write85(rle->data85, &c, 1); // length of non-run data write85(rle->data85, rle->buffer, rle->count); // non-run data rle->count = 0; } rle->buffer[rle->count++] = b; // add byte to end of non-run buffer } void Fl_PostScript_Graphics_Driver::close_rle85(void *data) // stop doing RLE+ASCII85 encoding { struct_rle85 *rle = (struct_rle85 *)data; uchar c; if (rle->run_length > 0) { // if within a run, output it c = (uchar)(257 - rle->run_length); write85(rle->data85, &c, 1); write85(rle->data85, rle->buffer, 1); } else if (rle->count) { // output the non-run buffer, if not empty c = (uchar)(rle->count - 1); write85(rle->data85, &c, 1); write85(rle->data85, rle->buffer, rle->count); } c = (uchar)128; write85(rle->data85, &c, 1); // output EOD mark close85(rle->data85); // close ASCII85 encoding process delete rle; } // // End of implementation of the /RunLengthEncode + /ASCII85Encode PostScript filter // int Fl_PostScript_Graphics_Driver::alpha_mask(const uchar * data, int w, int h, int D, int LD){ mask = 0; if ((D/2)*2 != D){ //no mask info return 0; } int xx; int i,j, k, l; LD += w*D; int V255=0; int V0 =0; int V_=0; for (j=0;j<h;j++){ for (i=0;i<w;i++) switch(data[j*LD+D*i+D-1]){ case 255: V255 = 1; break; case 0: V0 = 1; break; default: V_= 1; } if (V_) break; }; if (!V_){ if (V0) if (V255){// not true alpha, only masking xx = (w+7)/8; mask = new uchar[h * xx]; for (i=0;i<h * xx;i++) mask[i]=0; for (j=0;j<h;j++) for (i=0;i<w;i++) if (data[j*LD+D*i+D-1]) mask[j*xx+i/8] |= 1 << (i % 8); mx = w; my = h; //mask imensions return 0; } else { mask=0; return 1; //everything masked } else return 0; } ///// Alpha dither, generating (4*w) * 4 mask area ///// ///// with Floyd-Steinberg error diffusion ///// mask = new uchar[((w+1)/2) * h * 4]; for (i = 0; i<((w+1)/2) * h * 4; i++) mask[i] = 0; //cleaning mx= w*4; my=h*4; // mask dimensions xx = (w+1)/2; // mask line width in bytes short * errors1 = new short [w*4+2]; // two rows of dither errors short * errors2 = new short [w*4+2]; // two rows of dither errors for (i=0; i<w*4+2; i++) errors2[i] = 0; // cleaning,after first swap will become current for (i=0; i<w*4+2; i++) errors1[i] = 0; // cleaning,after first swap will become current short * current = errors1; short * next = errors2; short * swap; for (j=0; j<h; j++){ for (l=0; l<4; ){ // generating 4 rows of mask lines for 1 RGB line int jj = j*4+l; /// mask row index swap = next; next = current; current = swap; *(next+1) = 0; // must clean the first cell, next are overriden by *1 for (i=0; i<w; i++){ for (k=0; k<4; k++){ // generating 4 x-pixels for 1 RGB short error, o1, o2, o3; int ii = i*4+k; // mask cell index short val = data[j*LD+D*i+D-1] + current[1+ii]; if (val>127){ mask[jj*xx+ii/8] |= 1 << (ii % 8); //set mask bit error = val-255; }else error = val; ////// error spreading ///// if (error >0){ next[ii] += o1 = (error * 3 + 8)/16; current[ii+2] += o2 = (error * 7 + 8)/16; next[ii+2] = o3 =(error + 8)/16; // *1 - ok replacing (cleaning) } else { next[ii] += o1 = (error * 3 - 8)/16; current[ii+2] += o2 = (error * 7 - 8)/16; next[ii+2] = o3 = (error - 8)/16; } next[1+ii] += error - o1 - o2 - o3; } } l++; ////// backward jj = j*4+l; swap = next; next = current; current = swap; *(next+1) = 0; // must clean the first cell, next are overriden by *1 for (i = w-1; i >= 0; i--){ for (k=3; k>=0; k--){ // generating 4 x-pixels for 1 RGB short error, o1, o2, o3; int ii = i*4+k; // mask cell index short val = data[j*LD+D*i+D-1] + current[1+ii]; if (val>127){ mask[jj*xx+ii/8] |= 1 << (ii % 8); //set mask bit error = val-255; } else error = val; ////// error spreading ///// if (error >0){ next[ii+2] += o1 = (error * 3 + 8)/16; current[ii] += o2 = (error * 7 + 8)/16; next[ii] = o3 =(error + 8)/16; // *1 - ok replacing (cleaning) } else { next[ii+2] += o1 = (error * 3 - 8)/16; current[ii] += o2 = (error * 7 - 8)/16; next[ii] = o3 = (error - 8)/16; } next[1+ii] += error - o1 - o2 - o3; } } l++; } } delete[] errors1; delete[] errors2; return 0; } // bitwise inversion of all 4-bit quantities static const unsigned char swapped[16] = {0,8,4,12,2,10,6,14,1,9,5,13,3,11,7,15}; // bitwise inversion of a byte static inline uchar swap_byte(const uchar b) { return (swapped[b & 0xF] << 4) | swapped[b >> 4]; } extern uchar **fl_mask_bitmap; struct callback_data { const uchar *data; int D, LD; }; static void draw_image_cb(void *data, int x, int y, int w, uchar *buf) { struct callback_data *cb_data; const uchar *curdata; cb_data = (struct callback_data*)data; curdata = cb_data->data + x*cb_data->D + y*cb_data->LD; memcpy(buf, curdata, w*cb_data->D); } void Fl_PostScript_Graphics_Driver::draw_image(const uchar *data, int ix, int iy, int iw, int ih, int D, int LD) { if (D<3){ //mono draw_image_mono(data, ix, iy, iw, ih, D, LD); return; } struct callback_data cb_data; if (!LD) LD = iw*D; cb_data.data = data; cb_data.D = D; cb_data.LD = LD; draw_image(draw_image_cb, &cb_data, ix, iy, iw, ih, D); } void Fl_PostScript_Graphics_Driver::draw_image(Fl_Draw_Image_Cb call, void *data, int ix, int iy, int iw, int ih, int D) { double x = ix, y = iy, w = iw, h = ih; int level2_mask = 0; fprintf(output,"save\n"); int i,j,k; const char * interpol; if (lang_level_ > 1) { if (interpolate_) interpol="true"; else interpol="false"; if (mask && lang_level_ > 2) { fprintf(output, "%g %g %g %g %i %i %i %i %s CIM\n", x , y+h , w , -h , iw , ih, mx, my, interpol); } else if (mask && lang_level_ == 2) { level2_mask = 1; // use method for drawing masked color image with PostScript level 2 fprintf(output, " %g %g %g %g %d %d pixmap_plot\n", x, y, w, h, iw, ih); } else { fprintf(output, "%g %g %g %g %i %i %s CII\n", x , y+h , w , -h , iw , ih, interpol); } } else { fprintf(output , "%g %g %g %g %i %i CI", x , y+h , w , -h , iw , ih); } int LD=iw*D; uchar *rgbdata=new uchar[LD]; uchar *curmask=mask; void *big = prepare_rle85(); if (level2_mask) { for (j = ih - 1; j >= 0; j--) { // output full image data call(data, 0, j, iw, rgbdata); uchar *curdata = rgbdata; for (i=0 ; i<iw ; i++) { write_rle85(curdata[0], big); write_rle85(curdata[1], big); write_rle85(curdata[2], big); curdata += D; } } close_rle85(big); fputc('\n', output); big = prepare_rle85(); for (j = ih - 1; j >= 0; j--) { // output mask data curmask = mask + j * (my/ih) * ((mx+7)/8); for (k=0; k < my/ih; k++) { for (i=0; i < ((mx+7)/8); i++) { write_rle85(swap_byte(*curmask), big); curmask++; } } } } else { for (j=0; j<ih;j++) { if (mask && lang_level_ > 2) { // InterleaveType 2 mask data for (k=0; k<my/ih;k++) { //for alpha pseudo-masking for (i=0; i<((mx+7)/8);i++) { write_rle85(swap_byte(*curmask), big); curmask++; } } } call(data,0,j,iw,rgbdata); uchar *curdata=rgbdata; for (i=0 ; i<iw ; i++) { uchar r = curdata[0]; uchar g = curdata[1]; uchar b = curdata[2]; if (lang_level_<3 && D>3) { //can do mixing using bg_* colors) unsigned int a2 = curdata[3]; //must be int unsigned int a = 255-a2; r = (a2 * r + bg_r * a)/255; g = (a2 * g + bg_g * a)/255; b = (a2 * b + bg_b * a)/255; } write_rle85(r, big); write_rle85(g, big); write_rle85(b, big); curdata +=D; } } } close_rle85(big); fprintf(output,"\nrestore\n"); delete[] rgbdata; } void Fl_PostScript_Graphics_Driver::draw_image_mono(const uchar *data, int ix, int iy, int iw, int ih, int D, int LD) { double x = ix, y = iy, w = iw, h = ih; fprintf(output,"save\n"); int i,j, k; const char * interpol; if (lang_level_>1){ if (interpolate_) interpol="true"; else interpol="false"; if (mask && lang_level_>2) fprintf(output, "%g %g %g %g %i %i %i %i %s GIM\n", x , y+h , w , -h , iw , ih, mx, my, interpol); else fprintf(output, "%g %g %g %g %i %i %s GII\n", x , y+h , w , -h , iw , ih, interpol); }else fprintf(output , "%g %g %g %g %i %i GI", x , y+h , w , -h , iw , ih); if (!LD) LD = iw*D; int bg = (bg_r + bg_g + bg_b)/3; uchar *curmask=mask; void *big = prepare_rle85(); for (j=0; j<ih;j++){ if (mask){ for (k=0;k<my/ih;k++){ for (i=0; i<((mx+7)/8);i++){ write_rle85(swap_byte(*curmask), big); curmask++; } } } const uchar *curdata=data+j*LD; for (i=0 ; i<iw ; i++) { uchar r = curdata[0]; if (lang_level_<3 && D>1) { //can do mixing unsigned int a2 = curdata[1]; //must be int unsigned int a = 255-a2; r = (a2 * r + bg * a)/255; } write_rle85(r, big); curdata +=D; } } close_rle85(big); fprintf(output,"restore\n"); } void Fl_PostScript_Graphics_Driver::draw_image_mono(Fl_Draw_Image_Cb call, void *data, int ix, int iy, int iw, int ih, int D) { double x = ix, y = iy, w = iw, h = ih; fprintf(output,"save\n"); int i,j,k; const char * interpol; if (lang_level_>1){ if (interpolate_) interpol="true"; else interpol="false"; if (mask && lang_level_>2) fprintf(output, "%g %g %g %g %i %i %i %i %s GIM\n", x , y+h , w , -h , iw , ih, mx, my, interpol); else fprintf(output, "%g %g %g %g %i %i %s GII\n", x , y+h , w , -h , iw , ih, interpol); } else fprintf(output , "%g %g %g %g %i %i GI", x , y+h , w , -h , iw , ih); int LD=iw*D; uchar *rgbdata=new uchar[LD]; uchar *curmask=mask; void *big = prepare_rle85(); for (j=0; j<ih;j++){ if (mask && lang_level_>2){ // InterleaveType 2 mask data for (k=0; k<my/ih;k++){ //for alpha pseudo-masking for (i=0; i<((mx+7)/8);i++){ write_rle85(swap_byte(*curmask), big); curmask++; } } } call(data,0,j,iw,rgbdata); uchar *curdata=rgbdata; for (i=0 ; i<iw ; i++) { write_rle85(curdata[0], big); curdata +=D; } } close_rle85(big); fprintf(output,"restore\n"); delete[] rgbdata; } ////////////////////////////// Image classes ////////////////////// void Fl_PostScript_Graphics_Driver::draw(Fl_Pixmap * pxm,int XP, int YP, int WP, int HP, int cx, int cy){ const char * const * di =pxm->data(); int w,h; if (!fl_measure_pixmap(di, w, h)) return; mask=0; fl_mask_bitmap=&mask; mx = WP; my = HP; push_clip(XP, YP, WP, HP); fl_draw_pixmap(di,XP -cx, YP -cy, FL_BLACK ); pop_clip(); delete[] mask; mask=0; fl_mask_bitmap=0; } void Fl_PostScript_Graphics_Driver::draw(Fl_RGB_Image * rgb,int XP, int YP, int WP, int HP, int cx, int cy){ const uchar * di = rgb->array; int w = rgb->w(); int h = rgb->h(); mask=0; if (lang_level_>2) //when not true, not making alphamask, mixing colors instead... if (alpha_mask(di, w, h, rgb->d(),rgb->ld())) return; //everthing masked, no need for painting! push_clip(XP, YP, WP, HP); draw_image(di, XP + cx, YP + cy, w, h, rgb->d(), rgb->ld()); pop_clip(); delete[]mask; mask=0; } int Fl_PostScript_Graphics_Driver::draw_scaled(Fl_Image *img, int XP, int YP, int WP, int HP){ int X, Y, W, H; clip_box(XP,YP,WP,HP,X,Y,W,H); // X,Y,W,H will give the unclipped area of XP,YP,WP,HP if (W == 0 || H == 0) return 1; push_no_clip(); // remove the FLTK clip that can't be rescaled clocale_printf("%d %d %i %i CL\n", X, Y, W, H); clocale_printf("GS %d %d TR %f %f SC GS\n", XP, YP, float(WP)/img->w(), float(HP)/img->h()); img->draw(0, 0, img->w(), img->h(), 0, 0); clocale_printf("GR GR\n"); pop_clip(); // restore FLTK's clip return 1; } void Fl_PostScript_Graphics_Driver::draw(Fl_Bitmap * bitmap,int XP, int YP, int WP, int HP, int cx, int cy){ const uchar * di = bitmap->array; int w,h; int LD=(bitmap->w()+7)/8; int xx; if (WP> bitmap->w() - cx){// to assure that it does not go out of bounds; w = bitmap->w() - cx; xx = (bitmap->w()+7)/8 - cx/8; //length of mask in bytes }else{ w =WP; xx = (w+7)/8 - cx/8; } if ( HP > bitmap->h()-cy) h = bitmap->h() - cy; else h = HP; di += cy*LD + cx/8; int si = cx % 8; // small shift to be clipped, it is simpler than shifting whole mask int i,j; push_clip(XP, YP, WP, HP); fprintf(output , "%i %i %i %i %i %i MI\n", XP - si, YP + HP , WP , -HP , w , h); void *rle85 = prepare_rle85(); for (j=0; j<HP; j++){ for (i=0; i<xx; i++){ write_rle85(swap_byte(*di), rle85); di++; } } close_rle85(rle85); fputc('\n', output); pop_clip(); } #endif // FL_DOXYGEN // // End of "$Id: image.cxx 4324 2005-05-09 21:47:22Z rokan $" //